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DESIGN AND OPERATION OF DC MICROGRID FOR
INTEGRATION OF HYBRID RENEWABLE POWER

SUBMITTED IN PARTIAL FULFILLMENT OF THE
REQUIREMENT FOR AWARD OF DEGREE OF

MASTER OF TECHNOLOGY
(POWER SYSTEM)

SUBMITTED BY
NATASHA MAHAJAN

University Roll No.: 1908605

UNDER THE ESTEEMED GUIDANCE OF
Dr. Vibhuti
Head of Department

July, 2024

I.K. GUJRAL PUNJAB TECHNICAL UNIVERSITY
JALANDHAR (PUNJAB), INDIA
SRI SAI COLLEGE OF ENGINEERING & TECHNOLOGY, BADHANI
 CANDIDATE'S DECLARATION CERTIFICATE

I hereby certify that the work which is being presented in this Thesis, entitled “Design
And Operation of DC Microgrid for Integration of Hybrid Renewable Power” by
NATASHA MAHAJAN in partial fulfillment requirement for the award of degree of
M. Tech. (Power System) submitted in the Department of Electrical Engineering at Sri
Sai College of Engineering & Technology Badhani, Pathankot under IK Gujral
Punjab Technical University, Jalandhar is an authentic record of my own thesis
work carried out under the supervision of Dr. VIBHUTI, Head of Department. The
matter presented in this thesis has not been submitted by me in any other
University/Institute for the award of M. Tech. Degree.

NATASHA MAHAJAN
Roll No.: 1908605
This is to certify that the above statement made by the candidate is correct to the best
of my knowledge.

Guide:
Dr. Vibhuti Dr. Vibhuti
Head of Department Head of Department
Department of Electrical Engg. Department of Electrical Engg.
Sri Sai College of Engg. & Tech. Sri Sai College of Engg. & Tech.
Badhani, Pathankot Badhani, Pathankot

The M.Tech. Viva-Voce Examination of Natasha Mahajan has been held
on and is accepted.

Signature of Guide Signature of External Examiner

Signature of H.O.D

i
 ACKNOWLEDGEMENT

While bringing out this thesis to its final form, I came across a number of people whose
contributions in various ways helped my field of research and they deserve special
thanks. It is a pleasure to convey my gratitude to all of them.

First and foremost, I would like to express my deep sense of gratitude and indebtedness
to my supervisor Dr. Vibhuti, Head of Department, Electrical Engineering Department
at Sri Sai College of Engineering & Technology Badhani, Pathankot for her invaluable
encouragement, suggestions and support from an early stage of this research and
providing me extraordinary experiences throughout the work. Above all, her priceless
and meticulous supervision at eachand every phase of work inspired me in innumerable
ways. Her expertise and encouragement helped me to complete this research paper and
write this thesis.

I specially acknowledge her for her advice, supervision, and the vital contribution as
and when required during this research. Her involvement with originality has triggered
and nourished my intellectual maturity that will help me for a long time to come. I am
proud to record that I had the opportunity to work with an exceptionally experienced
Professor like her.

I am grateful to Dr. VIPIN GUPTA, principal, for providing me with the opportunity
to conduct my research at Sri Sai College of Engineering & Technology Badhani,
Pathankot, and for all of the resources and support they provided.

Finally, I am deeply indebted to my mother, Mrs. Sarita Gupta, my father, Mr.
Rakesh Chander Gupta, my elder brother, Rahil Mahajan, and to my other family
members for their moral support and continuous encouragement while carrying out this
study. Without them, this journey would not have been possible.

Lastly, I would like to thank all of the participants in my study for their time and
willingness to share their experiences. This work would not have been possible without
their contribution.

NATASHA MAHAJAN
ROLL NO: - 1908605

ii
 ABSTRACT

The increasing demand for clean and sustainable energy solutions, the concept of
microgrids has gained significant attention in recent years. A microgrid is a localized
power distribution system that can operate independently or in conjunction with the
main grid, enabling the integration of renewable energy sources, energy storage, and
advanced control techniques. Among various types of microgrids, Direct Current (DC)
microgrids have emerged as a promising alternative to traditional Alternating Current
(AC) grids, offering numerous advantages in terms of efficiency, reliability, and
resilience. Unlike conventional AC grids, which rely on alternating current for power
transmission and distribution, DC microgrids utilize direct current. This shift from AC
to DC power distribution brings several benefits. This study presents a comprehensive
analysis of the performance and benefits of DC microgrids as a sustainable and efficient
solution for power distribution.

The research begins by formulating the problem, identifying the challenges, and
defining the objectives. The methodology involves designing and simulating the
Photovoltaic (PV) system and wind farm to capture maximum power output. To analyze
the performance of the microgrid during fault occurrences, different fault scenarios are
simulated on the AC grid section. The behavior of the microgrid under these fault
conditions is studied, and the response of the PV and wind sources, as well as the energy
storage system, is evaluated. To achieve this, a simulation model was developed using
MATLAB/Simulink to assess the performance of the DC microgrid system under
different scenarios. The simulations demonstrate that the combined power generated by
PV panels and wind turbines in the DC microgrid reaches approximately 10 kW,
showcasing their capacity to provide a consistent and reliable power supply. The
findings reveal that the DC microgrid effectively utilizes renewable energy sources to
supply power to the load, while the AC grid provides backup power during fault
situations. The energy storage system plays a crucial role in managing power
fluctuations and stabilizing the grid. The integration of various power sources and
control algorithms ensures a reliable and efficient power distribution system. In
addition to power generation, the simulations also consider the response of the DC
microgrid system to fault scenarios occurring in the AC grid. The results reveal that the
DC microgrid exhibits seamless transitions and achieves a fast recovery time of 0.1 to
0.15 seconds.

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 TABLE OF CONTENTS

Title

Candidate’s Declaration Certificate i

Acknowledgement ii

Abstract iii

Table of Contents iv-v

List of Abbreviations vi

List of Figures vii-ix

List of Tables x

Chapter 1: Introduction 1-10

1.1 Introduction 1-2

1.2 Dc Microgrid Systems 2-5

1.3 Constant Power Loads in Microgrids 5

1.4 Protection Strategy for Dc Microgrid 6-7

1.5 Dc Microgrid Control Strategies 7-10

Chapter 2: Literature Review 11-24

2.1 Literature Survey 11-24

Chapter 3: Problem Formulation and Objectives 25-27

3.1 Problem formulation 25-26

3.2 Problem Statement 27

3.3 Objectives 27

Chapter4: Methodology 28-32

4.1 Introduction 28

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4.2 Methodology 28-32

Chapter 5: Results and Discussions 33-53

5.1 Introduction 33

5.2 Analysis of Fault with Grid and PV Based DC-Microgrid 33-41

5.3 Analysis of Fault with Grid and Wind Farm Based DC-Microgrid 41-49

5.4 Analysis of DC-Microgrid with PV, Wind and AC Source 49-53

5.5 Summary 53

Chapter 6: Conclusions And Future Scope 54-55
6.1 Conclusions 54
6.2 Future Scope 55
References 56-65
List of Publications 66

v
 LIST OF ABBREVIATIONS

PV Photo voltaic

MG Microgrid

DGS Distributed generation system

LV Low voltage

MV Medium voltage

ESS Energy storage system

LVDC Low voltage distribution system

CPL Constant power loads

CVL Constant voltage loads

LQR Linear-quadratic regulator

PID Proportional integral derivative

BESS Battery energy storage systems

MPPT Maximum power point tracking

AC Alternating Current

DC Direct Current

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 LIST OF FIGURES

Page No

Figure 1.1 Typical configuration of a conventional DC microgrid. 3

Figure 1.2 DC micro-grids' protection issues and solutions. 6

Figure 1.3 Hierarchical control layers of a microgrid. 8

Figure 1.4 Hierarchical control architecture. 9

Figure 1.5 Three DC microgrid control methods. 10

Figure 4.1 DC-microgrid designed using MATLAB/Simulink. 29

Figure 4.2 Designed PV system in MATLAB/Simulink. 31

Figure 4.3 Wind farm model designed in MATLAB/Simulink. 32

Figure 4.4 Designed storage system for dc-microgrid. 32

Figure 5.1 Irradiance of the PV plant started at t=0 sec. 34

Figure 5.2 Power delivered to load by PV plant. 34

Figure 5.3 Output from ac-grid from t =0 to t=1 sec. 35

Figure 5.4 Irradiance of the PV plant started at t=1 sec. 35

Figure 5.5 Combined power delivered to load by ac-grid (from t=0 to 36

t=1 sec) and PV plant (from t=1 to t=5 sec).

Figure 5.6 Output from ac-grid from t =0 to t=2 sec. 36

Figure 5.7 Irradiance of the PV plant started at t=2 sec. 37

Figure 5.8 Combined power delivered to load by ac-grid (from t=0 to 37

t=2 sec) and PV plant (from t=2 to t=5 sec).

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Figure 5.9 Output from ac-grid from t =0 to t=3 sec. 38

Figure 5.10 Irradiance of the PV plant started at t=3 sec. 38

Figure 5.11 Combined power delivered to load by ac-grid (from t=0 to 39

t=3 sec) and PV plant (from t=3 to t=5 sec).

Figure 5.12 Output from ac-grid from t =0 to t=4 sec. 39

Figure 5.13 Irradiance of the PV plant started at t=4 sec. 40

Figure 5.14 Combined power delivered to load by ac-grid (from t=0 to 40

t=4 sec) and PV plant (from t=4 to t=5 sec).

Figure 5.15 Wind speed profile from t=0 to t=5 sec. 42

Figure 5.16 Power delivered to load by wind farm (from t =0 to t=5 42
sec).

Figure 5.17 Output from ac-grid from t =0 to t=1 sec. 43

Figure 5.18 Wind speed profile from t=1 to t=5 sec. 43

Figure 5.19 Combined power delivered to load by ac- grid (from t=0 to 44

t=1 sec) and wind farm (from t=1 to t=5 sec).

Figure 5.20 Output from ac grid from t=0 to t=2 sec. 44

Figure 5.21 Wind speed profile from t=2 to t=5 sec. 45

Figure 5.22 Combined power delivered to load by ac-grid (from t=0 to 45

t=2 sec) and wind farm (from t=2 to t=5 sec).

Figure 5.23 Output from ac-grid from t =0 to t= 3 sec. 46

Figure 5.24 Wind speed profile from t = 3 to t = 5 sec. 46

Figure 5.25 Combined power delivered to load by ac-grid (from t=0 to 47

viii
 t=3 sec) and wind farm (from t=3 to t=5 sec).

Figure 5.26 Output from ac-grid from t =0 to t= 4 sec. 47

Figure 5.27 Wind speed profile from t = 4 to t = 5 sec. 48

Figure 5.28 Combined power delivered to load by ac-grid (from t= 0 to 48

t=4 sec) and wind farm (from t=4 to t=5 sec).

Figure 5.29 Three phase output from the grid. 50

Figure 5.30 Irradiance intensity input to PV panel. 50

Figure 5.31 Power output profile of PV plant. 51

Figure 5.32 Nominal excitation applied to wind farm. 51

Figure5.33 SOC of the batteries. 52

Figure 5.34 Bus voltage profile during complete simulation time. 52

Figure 5.35 Power delivered to load connected to the system. 53

ix
 LIST OF TABLES

Table 1.1 Few common example of DC micro-grid in practice 4

Table 5.1 Response of dc-microgrid with PV source and fault at 41
ac-grid section.

Table 5.2 Response of dc-microgrid with wind farm source and 49
fault at ac-grid section.

x
 CHAPTER 1

INTRODUCTION

1.1 Introduction

Due to its advantages over conventional Alternating Current (AC) systems for
distributing power according to power density, Direct Current (DC) power
distribution systems, and power distribution effectiveness, also known as DC micro-
grids, are of great interest for a variety of power applications. Alternatively, short-
circuit flaws in these systems pose serious risks. Due to the nonappearance of
ordinary crossing zero of DC current, it is challenging to extinguish these arc faults
with standard circuit breakers. Additionally, DC breakers are often more expensive
and larger. Today, these systems' failure protection, to the magnitude that it even
exists, is dependent on data networks, excess current timeout limitations in power
converters, or dedicated circuit breakers that trip through overcurrent or distance
relays. More reliable, completely distributed, communication-independent techniques
are required. Interest in distributed generating systems using photovoltaic energy
(solar and thermal), wind, biomass, mini-hydro, as well as use of fuel cells and micro
turbines, has significantly increased in recent years. Due to the significant benefits
they can offer, they are now accepted methods for reducing environmental pollution,
addressing long-distance transmission issues, providing uninterruptible power,
meeting high loads that occur suddenly and enhancing equipment performance.
However, using Distributed Generation System (DGS) on a large scale has some
drawbacks, a hefty price for single generation access, for instance and making it is
more difficult to control. When DGS has a consequence on system energy and
frequency from the grid point, such as the grid must shut down when it is separated
since the other of the power system to craft a localised system powered by DGS. The
advantages and potential of DGS are further undermined by the requirement for DGS
to leave the system quickly in the event of accidental incidents. The idea of microgrid
is introduced to resolve the conflict between the system and DGS [1–5].

A network of scattered energy resources, loads, and distribution network
elements that may function in either grid linked or islanded approaches that are
coordinated and managed inside undoubtedly defined geographic confines is known

1
as a micro-grid (MG). The key advantages of adopting a microgrid include expanding
the supply of renewable energy, enhancing system independence/security, and
boosting dependability [1-2, 6]. The distributed generation and controllable loads
that could be linked to the average voltage grid or operated in a meticulous,
synchronized manner on an island were all factors that were being taken into account
when the MG concept was first anticipated in 2002 as a basis for the development of
forthcoming low-voltage distribution systems.

MG was founded on the concept of combining several micro sources and
loads into a single distinct object, it might be considered one dispatchable consumer
in the context of the overhead power system. In addition, it provides utilities,
society, and end users with a number of benefits, including:

1. Enhanced energy effectiveness

2. Decreased total energy use

3. Decreased emissions of greenhouse gases and other pollutants

4. Enhanced dependability and quality of service

5. Cost-effective replacement of the electrical infrastructure.

Microgrids clearly benefit end users, utilities, and society in terms of the economy
and ecology, but implementing them presents significant technological difficulties,
such as microgrid protection. Recently, hybrid MGs with both AC and DC MGs
have been projected for a diversity of applications [11–16]. Research on DC MGs has
recently increased to help with the integration of modern electronic loads and
unconventional energy sources with dc output types, such as fuel cells, photovoltaic
(PV) systems, and energy storages (such as lesser batteries and super-capacitors),
while ac MGs have received the majority of the attention [16–17].

1.2 DC Microgrid Systems

Significant energy savings may be realised by connecting sources of DC electricity
and DC loads directly, avoiding employing a DC power distribution system and
converting DC-AC-DC energy, given the usage of the most energy-efficient electric

2
appliances, which operate internally on DC [7–12, 16–17]. This distribution strategy
offers a more dependable and efficient energy transfer than traditional AC, it has been
shown. The adoption of diverse DC power distribution systems is increasing as a
result of these and other advantages including avoiding issues with harmonics,
unhinges, synchronisation, and reactive power flows. As a result, DC-internal loads
including electric vehicles, efficient DC motors, business data centres, fluorescent
and Light Emitting Diode (LED) lighting systems, and all consumer gadgets will
endure to grow quickly in both home and salable applications. A number of DC-DC
converters are present in the typical DC micro-grid shown in Figure 1.1 in order to
supply the necessary voltage level for all connected DC loads. The absence of
reactive power and harmonics in this system, as one may anticipate, results in
greater power quality and system efficiency [7, 12, 16–17].

Figure 1.1: Typical configuration of a conventional DC microgrid

Any MG can be operated in either a grid-connected mode or an islanding
(standalone) mode, and the details of each of these two MG operation modes are
provided below: It's in "On- grid mode" when it's connected to the utility system, also
referred to as "grid-connected mode." Depending on the location and overall
capabilities of the installed DG units, the MG is frequently connected in this fashion
to the major medium voltage (MV), such as 11-66 kV, or low voltage (LV), such as

3
110-690 V grids. It supplies the main utility with some electricity, either
directly or indirectly, and uses that electricity to power the nearby loads.
Additionally, the main functions of DG units in micro-grid systems are to provide
local and power support as well as electricity generation. By directing the creation of
regulated active and reactive powers in MGs utilizing interface power converters such
DC/DC and DC/AC converters, the controller may direct the reference values of each
DG unit. A few DG units, like those found in wind turbines and solar panel arrays,
can also be controlled to generate their MPP. The utility is immediately severed from
the MG. upon the onset of a failure and its associated switching events and provides it
loads locally. In this instance, the MG is operating independently in a manner similar
to physical islands when it is cut off from the main network. This mode is sometimes
referred to as "Off-grid mode" or "islanding mode." If the electricity produced by the
DGs of the MG is inadequate to supply all of its local demands during islanding,
load shedding may be used [28–30]. Table 1.1 provides examples of common DC
MG systems that are used for most data centre's or critical load applications, or are
utilized as testing prototypes.

TABLE 1.1 A Few Common Example of DC micro-grid in Practice

A DC micro-grid can utilise a single cable (monopolar dc link), two cables (bipolar
dc link), or even three cables (homopolar dc link) to transport electricity from the
primary utility, distributed generation (DG) units, and energy storage systems (ESSs)
through a shared DC distribution line. Low voltage distribution systems (LVDC
network) often use the homopolar configuration, but High Voltage (HVDC) long-
distance transmission networks frequently use the first two variations [2–3]. Any MG
essential function in grid connected and islanded mode without endangering grid

4
dependability, voltage and frequency stability, or shield structures, reliable with the
slight criteria for all associated devices, in order to evade any potential procedural
issues such as power, and energy equilibrium, power quality, or safety issues.

1.3 Constant Power Loads in Microgrids

Technology development has increased the use of power electronics devices, which
has led to a sharp rise in constant power loads (CPLs), which has a greater electrical
system integrity is affected., particularly micro-grid systems, a type of distributed
energy system. The majority of micro-grid systems place their loads on the
generating side. For the reason the supervision of load-associated protection is
essential to a micro-grid system, we choose load side compensation. Additionally, It
is point load correction to compensate for load side effects, meaning we can achieve
it at the precise point we want. Controllable loads and critical loads are two different
forms of micro-grid loads that may be categorized. Recharging stations for electric
vehicles, heat pumps, and other manageable loads as well as data centre's and falling
security measures under the type of crucial loads. For improved performance, critical
loads that include steady voltage loads as well as steady power loads must get the
appropriate attention. The good form of compensation for maintaining system
integrity is to manage such sensitive loads viewed from the load side. In micro-grid
applications, using load side compensation of Constant Power Load (CPLs)
instability brought on by the coupling of CPLs and Constant Voltage Load (CVLs) is
a useful approach. Additionally, by using this technique, we can manage the voltage
collapse phenomenon of all CPLs by combining them into a single branch. In that
situation, we just make up the difference where it is necessary.

Additionally, the microgrid bus/feeder is made up of a number of intermittent
sources with a constant voltage/generation mismatch. Therefore, providing
reimbursement from the feeder side or using intermediate circuitry is relatively
difficult and expensive. The suggested system must take these disturbances into
account if we combine these compensatory methods on feeder side or intermediary
circuitry. The further benefit of load side compensation arrangements over feeder side
or intermediary circuitry type arrangements is that they may be made portable.

5
1.4 Protection Strategy for DC Microgrid

In addition to earth fault prevention, integrated over-current and short-circuit
protection also covers DC Micro Grid (MG) failures. In addition, moulded cases with
DC circuit breakers, which are less expensive than fuses and over-current relays, can
be utilised to offer the DC MG short-circuit shield shown in Figure 1.2. The breaker
guards alongside power converter switching problems on the AC side. There are
two different failure kinds in a DC system. There are dual sorts of faults: line-to-
ground fault and line-to-line fault. The fault current route in a line-to-ground fault is
either between a downward line and the ground or a downward line and a negative
line. Between the positive line and the negative line, Line-to-line error is present.
Additionally, since a DC circuit lacks a natural "current zero," There must be a way to
zero out the current in the switch. To build an appropriate a DC system's grounding,
two opposing objectives must be met: i.e., minimising the DC current; and increasing
people security by minimising the voltage in the common mode Consequently, at the
same voltage and current, the contacts are under more stress in a DC switch than an
AC one. Other uses necessitate construction of unique DC breakers, except in rare
instances where it is conceivable to utilise an overvalued DC-based AC circuit
breaker circuits. Additionally, because to the low DC impedance in DC systems, DC
faults levels are quite high.

Figure 1.2: DC micro-grids' protection issues and solutions

6
According to Figure 1.2, increasing grid stability is the aim of grid compliance. One
such criterion is the Low Voltage Ride Through (LVRT) capability, or the power
plant's capacity to maintain grid connectivity by actively supplying reactive power up
until fault clearance, during voltage decreases, and to a power system's stability. The
coordination of the protective relays may be endangered by the use of reactive power
during a grid failure. Alternatives for Micro-grid Protection Plans as shown in
Figure. 1.2, given that a few ways to increase the security and safety capabilities of
micro-grids [53-54]. Following is a brief explanation of each of the solutions listed in
Figure. 2

 Adaptive Protection: Existing overcurrent relays should offer the necessary
sensitivity and selectivity due to the varying fault levels during off-grid and
on-grid modes.

 Current Limiting: To prevent equipment damage and safety concerns, current
limiting is necessary.

 Virtual Impedance: In addition to aiding in the regulation of power flow,
virtual impedance has the ability to smooth out harmonics, create an intended
dynamic, and allow for ride-through of errors.

 Fault Current Limiter: During a fault condition, the DG shall remain
connected to the grid in accordance with the LVRT criteria.

 To satisfy the needs for the smart grid, a promising islanding detection
approach is needed.

 Standardisation: The implementation calls for highly dependable,
affordable, and quick communication standards as well as utility codes.

1.5 DC Microgrid Control Strategies

The use of advanced control techniques is essential for micro-grids. There are
various control techniques available to achieve this purpose. A linear control is the
most often used control method. Its popularity has grown as a result of its reliability
and simplicity. In contrast, linear control, as the name implies, takes into account an
operational point-centered linear model. This suggests that the operational point is the

7
sole region where the simplified model is applicable. There are several methods
regarding linear control in micro-grids. For instance include either transfer
coefficients or state space modelling, in which the allocation of poles using the State
feedback, the linear quadratic regulator, and comparative integral derivative are also
viable solutions.

The system's entire model serves as the foundation for nonlinear control
method, on the other hand. It follows that the nonlinear operation dynamics are taken
into account. The more true-to-life grid modelling and the fact that not a model
constrained to run in a circle around the operational point are advantages of nonlinear
control method. Even so, a disadvantage a nonlinear control approach is the
complicated evaluation and challenging control legislation implementation.
Hierarchical control at several layers is developed to make sure the microgrid is
properly controlled. A assured amount of unconventionality among various control
levels is provided by these control layers. Additionally, there are numerous control
layers the benefit of being more trustworthy because they continue to function even in
the event that the centralised control layer fails. Figure 1.3 depicts the three
layers used in hierarchical micro-grid control.

Figure1.3: Hierarchical control layers of a microgrid

8
For current, voltage, and power sharing, conventional hierarchical control systems are
suggested. Figure 1.4 depicts the categorized control architecture, which includes
the primary, secondary, and tertiary control levels. The system's reaction time is
determined by the bandwidth. It is a gauge of how long it takes to react to a command
change in input. The graph demonstrates that primary control has the quickest
response time compared to tertiary control, which takes the longest to react to a
change in system variables.

Figure 1.4: Hierarchical control architecture

The bottom rung of the control hierarch, or primary control, is sometimes mentioned
to as indigenous control or internal control and includes the fastest reaction. A few
seconds are the time frame in which this control layer functions. When a
disturbance affects The primary control layer is in care of managing the current and
voltage in the microgrid in mandate to adjust the operating points of the grid while
the secondary controller computes the new set of optimal operation values.

The power quality is under secondary control. This suggests the ideal power flow to
maintain system power balance. Each power source in the network has its power;
there are three different techniques to implement the secondary control layer
generation controlled by this control layer, as illustrated in Figure 1.5, from a
communication-based approach.

9
 Figure 1.5: Three DC microgrid control methods

No necessity for communication in decentralised control. This control method solely
defines its control actions using measurable local information. As a result, all
Distributed Generation Unit (DGUs) are independent of one another and
communication, enabling parallel operation. All sensor data, such as micro-grid
statuses, is transferred in centralised control from the DGUs to a central controller
Micro grid Central Controller (MGCC). All of the incoming data is processed by this
central controller, which then transmits control actions back. Since the central
controller has real-time information about every power source, the microgrid can
perform as well as it possibly can. The controls depend on the communication
network's dependability, which is a disadvantage. There is no need for a centralised
controller in dispersed control. To perform at their best, DGUs only share their states
with their immediate neighbours. The principal advantage of this method is that a
DGU solely depends on communication with its neighbours. Therefore, provided that
the communication network is active, the system can endure to function properly
even if some communication links fail. This suggests that single point of failure
(SPOF) cannot affect distributed control. In the hierarchy control scheme, tertiary
control is the uppermost layer, and it responds slowly. The energy market is covered
in this layer, which organises the energy dispatch schedule from an economic
perspective while taking into consideration negotiations between customers and
providers. Social issues and human-machine interaction are also covered at this level.

10
 CHAPTER 2

LITERATURE REVIEW

2.1 Literature Review

In microgrids, dc is often preferred to ac for three reasons: First off, distribution level
transformer-free power systems are now feasible owing to the swift advancement of
power electronics technology. Second, dc systems require fewer power conversion
steps when several ac and dc loads are associated to the same bus. Third, due to the
skin effect, dc current can travel through the entire cable while ac current only passes
through the outer surface of a cable. Dc systems may therefore offer times more
power than ac systems for power lines of the same size. The current DC microgrid
modelling, control, and theoretical stability analysis techniques are thoroughly
examined in this chapter.

Wu et al (2022) proposed solution for reducing the contravention
compression of a solid-state circuit breaker while eradicating DC faults and
enhancing fault current restraint is the current restrictive solid-state circuit breaker
topology. This construction has compensations over conventional ones, especially in
the limitation of fault current and the cutting off of fault line speed. It works
particularly well for DC microgrids that are fast expanding and have a large amount
of fault current. The blocking process of this topology is theoretically examined in
this study, along with predictions of energy consumption and a design strategy for
important factors. Using Sabre software, a simulation model is made to verify the
proposal's viability. The findings show that the suggested structure performs
admirably in terms of fault isolation speed and can reduce the rising proportion of
fault current by 53.9%. The newly developed DC solid-state circuit breaker topology
in this study has a primary branch made up of a capacitor-blocking module and a
current-limiting component. This structure can prioritise the current-limiting branch
and carry out the proper fault cutoff operation based on the results of the fault
detection when the grid current is abnormal. The presence of the current-limiting
inductor slows the increase of the fault current, lowers the overcurrent amplitude,
minimises fault energy feed-in, speeds up fault clearance, and promotes dependable
grid operation.

11
 Hategekimana et al (2022) study reveals that the proposed fault detection
and isolation methods swiftly detect faults in the network and efficiently isolate the
faulty line segment, enabling the grid to be restored to its normal operation promptly.
Two algorithms, implemented in MATLAB/SIMULINK, are developed to analyze
fault occurrence and its isolation. The results indicate that these methods hold
promise for microgrid protection, effectively addressing fault detection and grid
restoration issues, especially in rural villages. The simulation outcomes demonstrate
that the proposed fault detection and isolation methods precisely identify and quickly
isolate the faulty section of the LVDC microgrid, leading to grid restoration and
continuous electricity supply to the unaffected areas. The line fault searching
approach is suggested among the ones put out because of how quickly the grid is
restored, improving grid performance as a whole. Additionally, by using relays
located at both ends of the grid line to interact with the DAB converter, the design
and modelling of this technology help to shorten the time it takes to discover faults.
The suggested grid protection approach is appropriate for a variety of LVDC
microgrid systems, particularly in rural communities, and successfully addresses
issues with fault detection and isolation.

Reddy et al (2022) proposed protection scheme is of great importance due to
the current limit converters and bidirectional power flow in ring-configured systems.
It efficiently finds issues like faults and unexpected load switching. The protection
approach makes use of oscillation frequency and estimated inductance by
investigating fault current characteristics and capacitor-discharge. This method
effectively distinguishes between internal and external faults and, in the instance of
internal problems, provides the location of the defect. The simulation experiments
demonstrate that, despite diverse abnormal circumstances, the projected fault site is
unchanged, enhancing relay dependability, particularly for high fault resistances. In
this study, a novel protective strategy is suggested to address these problems. Starting
with the difference in successive current sample data, it evaluates the current
difference index. This non-zero index makes it possible to distinguish between
developing faults and sudden switching loads by estimating the fault frequency using
the inherent properties of fault current. Local voltage and current samples taken
during the fault are then utilised to estimate inductance, which provides information
on the polarity and size of the fault and its location, respectively. The suggested

12
approach is tested in MATLAB/Simulink under a variety of conditions, such as low
and high resistance faults, varied locations, bidirectional power flow, variable load
conditions, and other configurations. The outcomes show that the approach is
accurate in determining fault locations in each of these scenarios. This proposed
technique surpasses others, increasing relay dependability, according to a comparison
study using existing protective measures.

Pandey et al (2022) introduces an innovative fault detection and identification
method for low-voltage direct current (DC) microgrids with meshed
configuration. The technique is based on a graph convolutional network (GCN),
which uses measurement data from the network topology and explicit spatial
information to effectively find flaws even in the presence of noise and faulty data.
The adjacency matrix of the GCN is built using the network topology's inherent graph
representation, with node properties including bus voltage and line current samples
following faults. Using PSCAD/EMTDC to simulate the DC microgrid model, fault
scenarios are developed while taking into account a variety of environmental and
physical factors. Convolutional neural networks (CNN), support vector machines
(SVM), and fully connected networks (FCN) are compared with other machine
learning methods. The outcomes show that the suggested GCN-based method
performs better than the competition in fault detection and classification,
demonstrating superior resilience in the Nodes and edges of the graph are defined,
and network topology is incorporated to provide temporal and spatial information to
the fault data samples, enhancing classification accuracy. The method is extensively
evaluated through fault simulations involving variations in temperature, irradiance,
fault resistance, and fault distance. The experimental results showcase the method's
high accuracy in distinguishing various types of disturbances, including faults.
However, one limitation of the suggested process is its dependency on the grid
topology, as the adjacency matrix needs to be reconfigured when the topology
changes. To address this, future work may explore dynamic graph approaches to
handle frequent system-changing conditions and enhance the method's flexibility.

Ibrahim et al (2022) addresses the challenges involved in protecting DC
microgrids and explains fault detection techniques and design standards for effective

13
protective systems. The consequences of various protection solutions for DC
microgrids, such as those for line-to-ground and line-to-line faults, are discussed. The
research also offers DC fault current interrupting devices as viable remedies to
improve DC microgrid protection. However, safeguarding DC microgrids from
different defects is a difficult task. This is because DC power networks are special in
that they have plenty of big DC capacitors, low resistance DC connections, no natural
zero-crossing locations, and lots of transient current and voltage. The protection
challenges with DC microgrids are further complicated by converters with restricted
fault current, short lines, and practical grounding techniques. A substantial amount of
distributed generation has been integrated into utility networks as a result of the
growing use of renewable energy sources. This pattern has resulted in challenges in
quality, safety, and reliability are reviving interest in DC power systems. Due to their
reliance on power electronic components, DC microgrids provide an alluring solution
to these problems. They provide a practical method for integrating distributed energy
systems with power grids and exhibit outstanding performance in both grid-connected
and islanded modes.

Prince et al (2022) gives a comparative examination of the different
protection issues that DC microgrids with integrated converters, storage, and
distributed energy sources face. The development of an appropriate protection
mechanism is necessary due to the special characteristics of failures in DC
microgrids. In order to explore various topologies, protection and fault concerns, and
other pertinent issues in DC distribution systems, the study adopts a methodical
approach. Grounding and the absence of zero-crossing current, two crucial concerns
in DC microgrids, are thoroughly examined. Despite the operational benefits of DC
microgrids, a fundamental question surrounds their protective infrastructure. The
difficulties with grounding systems in DC microgrids are thoroughly investigated, as
well as the features of several grounding topologies. An adaptive protection strategy
is most useful in this situation because conventional protection strategies are
frequently ineffective for DC microgrids. Additionally, the protection devices for DC
microgrids should be designed in accordance with the characteristics of the fault
current. It is clear that additional academic research is needed to fully understand the
safety of DC systems due to the absence of norms and recommendations. By taking
the dynamic behaviour of renewable energy sources into account, models' accuracy

14
can be improved. For DC microgrids, a fault detection technique should be created
that is not dependent on the grid's fault impedance. The type of DC faults the system
experiences should determine the selection of an appropriate protection mechanism.

Zolfaghari et al (2022) emphasizes the prevalence of BILPCs as the primary
method for interconnecting HMGs. Among the control strategies for BILPCs, the
droop-control- established approaches have been widely utilized. Looking ahead,
future research endeavors may focus on enhancing the heftiness and tractability of the
existing control approaches or exploring novel approaches based on switched control
ideas. Additionally, unconventional approaches, such as small-scale Flexible AC
Transmission Systems (FACTS), could be considered as viable options for
interconnecting HMGs. These research directions hold potential for advancing the
efficiency and effectiveness of HMG interconnection techniques. The integration of
AC and DC microgrids forms the hybrid AC/DC microgrid (HMG), a crucial
element in the forthcoming implementation of smart grids. Within HMGs, the
interconnection of AC and DC microgrids and the control of bidirectional link power
converters (BILPCs) have received significant research attention over the past decade.
This study provides a thorough analysis of various connectivity strategies and control
issues related to AC and DC microgrids in HMGs.

Batmani et al (2022) presents a fault-tolerant control system using the
nonlinear state-dependent Riccati equation (SDRE) approach. The suggested system
is made up of three emergency controllers, a master controller, an observer-based
fault detection and isolation system, and an observer-based fault isolation system. As
a suboptimal nonlinear regulator, the master controller attempts to bring the DC
microgrid (MG) back to the intended equilibrium point during normal operation. The
goal of the SDRE observer is to offer a uniform platform for DC MG fault isolation
and detection. The suggested system may isolate the malfunctioning distributed
generation (DG) unit in the event of an unanticipated problem, and the emergency
controllers are immediately triggered to stabilise the MG. Results from simulations
show that the suggested approach is effective in attaining control goals and providing
online safety.

15
 Li and Chen et al (2022) introduces a novel DC microgrid cluster (SCMC)
having differential power processing features that is series-connected. The proposed
cluster comprises of n microgrids that may transmit power amongst one another
thanks to n bidirectional DC/DC converters. An additional converter is also included
to balance out current changes brought on by voltage variances. By using a series
architecture, the converter's one port voltage can be decreased to the voltage
difference between a microgrid and a bus, allowing the converters to process a
portion of the power and transmit the rest directly. This feature leads to improved
power density, reduced converter voltage stress, and enhanced overall efficiency. A
thorough examination of the system performance measures is done, along with a
comparison to more traditional methods that highlights the proposed SCMC's
undeniable advantages. Moreover, a case study of a three-microgrid cluster is used to
implement the design concerns and control methodologies. Experimental simulations
are used to further substantiate the theoretical analysis. The DC microgrid cluster
with differential power processing properties is series-connected offers a promising
solution for power transfer and distribution among microgrids, achieving significant
improvements in power density, cost reduction, and voltage stress reduction for
converters.

Rao and Jena (2022) presented simulations on a two-bus tapped DC
microgrid are used to validate the proposed architecture while taking into account
various failure situations, including high-resistance faults, variable fault locations,
and various distributed generation operation modes. Additionally, a lab-implemented
DC microgrid hardware bed is used to evaluate the proposed method under various
fault scenarios. Due to its efficiency and simplicity as compared to AC microgrids,
DC microgrids are becoming more and more popular. Protection strategies for tapped
line-based DC microgrids are still in the early phases of development, although a
variety of protection solutions are available for ring main and radial DC microgrid
topologies. The loads and distributed energy resources (DERs) in tapped line-based
medium-voltage direct current (MVDC) microgrids are connected at various places
along the line. Existing unit protection techniques, however, fail to detect system
problems when there is no communication link from the tapped line to any bus in the
microgrid. This article suggests a novel unit protection technique for tapped line
MVDC systems based on the idea of superimposed resistance to overcome this

16
problem. The suggested method is resilient to load changes and variations in power
generation at the tapping station since it uses prefault current data to determine the
tapping state. The findings show that the suggested unit protection approach for
tapped line-based MVDC microgrids is reliable and effective, providing a viable way
to improve the fault detection capabilities in such systems.

Prince et al (2022) proposes an efficient fault identification method for
safeguarding DC microgrids based on the actual and fictitious powers derived using
Fast Fourier Transform (FFT). When dispersed generators are integrated into DC
microgrids, weak fault currents in a variety of directions can result. This coordination
issue and difficulty for conventional over-current relays. To overcome this, strategies
for quick short-circuit fault detection and fault isolation protection are built using the
complicated power concept (real and imaginary). To provide fault isolation, solid-
state DC circuit breakers are used in conjunction with the real and imaginary power
that is proposed to be derived from the total FFT power signal (based on bus voltage
and line current). In the DC microgrid, relay trip threshold values for real and
fictitious power are established for a variety of pole-pole (P-P) and pole-ground (P-G)
failure scenarios. Using MATLAB/Simulink software, the suggested protection
method is tested on straightforward and modified IEEE 9-bus DC microgrids in
On/Off-Grid modes. The results of the simulations show how well the suggested
approach can identify faults in the simulated DC microgrids. A useful fault
identification method based on actual and fictitious FFT powers is also presented in
another paper for the protection of DC microgrids. The suggested approach uses
complex FFT power, real FFT power (RFFT), and imaginary FFT power (IFFT) to
identify and categorise errors at various DC microgrid locations. It is suggested to use
a relay trip threshold to recognise P-P and P-G faults with accuracy in various fault
scenarios.

Chen et al (2022) introduces a fresh approach to dealing with protection
issues in DC microgrids and networks, which frequently use DC-DC power
converters with lots of semiconductor-based power electronics to link renewable
energy sources and flexible loads. However, the majority of semiconductor devices
are only capable of withstanding a small number of faults, and traditional power
electronic protection solutions have problems with timing, self-destructing, and

17
judgement. The study suggests using a superconducting fault current limiter (SFCL)
to protect power electronic devices and expand its applicability to microgrids in order
to get around these restrictions. The SFCL serves as a passive current limiter that is
self-triggering, recoverable, and passive, thus no additional hardware or software is
required. The viability of applying this superconductor-based protection method to
produce self-acting fail-safe protection for DC-DC converters is shown through
experimental investigations and computer simulations. Additionally, system-level
simulations investigate how well the SFCL can handle millisecond-level faults and
transients in a photovoltaic-based DC microgrid by suppressing overcurrents and
stabilising bus voltage. The study establishes the framework for an interdisciplinary
application spanning power electronics, microgrids, and applied superconductivity
that is superconductor-semiconductor linked. The article expands the possible use of
superconductor-semiconductor coupling into microgrids and gives a preliminary
analysis on its use. It is a realistic solution for fail-safe protection of power electronic
switches and devices, especially in situations with millisecond-level transients and
faults, thanks to the self-acting features and advantages of the proposed compact-size,
low-cost SFCL. This innovative security method based on superconductors shows
potential for integration.

Gorji (2022) propose in the event of an open-circuit defect in its power
switch, three reconfigurable topologies of quadratic buck DC-DC converters can
seamlessly switch to semi-quadratic buck-boost converters. We establish a topology
that enables a secure switch transition while preserving optimal power conversion
with all other components by implementing graph-based circuit synthesis techniques.
It is well known that quadratic buck converters are efficient at providing certain
loads, like as electrolyzers, which need high current and low voltage.
Reconfigurability provides an added measure of security by ensuring that such loads
will always receive power. The proposed reconfigurable topologies are very
advantageous since an unwanted shutdown could have a negative effect on the life-
cycle of the load. We create three quadratic buck topologies and combine them with
three semi-quadratic buck-boost topologies using graph theory for electrical circuits.
These topologies effectively manage open-circuit faults by switching to a different
topology automatically using the other switch and using different routes for power
conversion. The high step-down voltage conversion ratio required by electrolyzer

18
applications makes the quadratic buck topologies ideal. The needs of the life-cycle of
an electrolyzer, where a constant power supply is essential, are well-aligned with the
reconfigurability of these circuits. Through simulations and lab prototypes, we verify
the suggested circuits' functionality. Future research can look at using the same
method for isolated topologies with input-output isolation requirements or look into
more degrees of freedom for altering the voltage gain ratio, like using transformers.

Thakur and Jain (2022) investigates the transient stability of DC microgrids,
whose integration into the distribution network is challenging because to
nonlinearities generated by converters. The analysis takes into account a number of
situations, including pole-to-ground failure, nonlinear load, nonlinear load with
dispersed generation, and linear load. A nonlinear decoupling method is used for
transient stability assessment in order to effectively analyse the high-order and
nonlinear character of DC microgrids. The findings demonstrate the importance of
DG as active power compensation when nonlinear loads are present, considerably
enhancing system active power as a whole. DG serves as a backup during faults,
powering the load. The nonlinear decoupling technique successfully addresses
nonlinear difficulties and is particularly suitable for evaluating transient stability in
DC microgrids. Results from simulations also show that certain system adjustments.

Mishra et al (2022) provides a thorough and current analysis of DC
microgrids (DCMG) and all of their facets. Researchers have been drawn to this area
of study by the growing interest in DCMGs as a practical means of supplying local
loads while strengthening the stability, reliability, and controllability of power
systems. DCMGs offer distinctive compared to AC microgrids, there are difficulties
and variances in topology, configuration, protection needs, and grounding. The
review technique calls for duties including compiling pertinent papers on microgrid
protection, weeding out the crucial ones using inclusion/exclusion criteria, and
evaluating each article critically. The paper discusses a wide range of DCMG
protection and grounding-related subjects and offers helpful insights into the
approaches put forth by diverse academics. It also makes suggestions and poses
queries for additional research in this field. The electrical utility sector has paid a lot

19
of attention to DC-based power generation, transmission, and distribution, which has
sparked the development of DC microgrids. While DCMGs have several advantages
over AC microgrids, they also have operational, control, and safety-related technical
difficulties. This study conducts a thorough analysis of the DCMG topology,
protection standards, problems, and difficulties, as well as safety equipment and fixes.
It covers the significance of grounding in the DC distribution network and outlines
the essential requirements for DCMG protection, such as fault detection, location, and
classification. Comparisons with AC microgrid protection systems and high voltage
DC transmission show that DCMG protection is still an area that needs more
investigation. The study highlights the possibility that protection measures and
equipment used in AC systems.

Baidya and Nandi (2022) study It turns out that, despite the fact that each
mode of DC Microgrids provides unique issues linked to faults, the majority of
protection strategies are made to accommodate both islanded and grid-connected
modes. Continuous study is needed in this area to build a protection strategy that is
both economical and sensible. While identifying and isolating defective components
from the functioning system, the optimum protection solution should provide
precision, sensitivity, quick response, low power loss, small size, long life, and cost
effectiveness. Future research must focus on managing both protection units and
upstream and downstream devices. Extending research on protective areas including
converter topology, IoT, Blockchain Technology, AI, Machine Learning, and Deep
Learning holds enormous potential given the sizeable amount of electronic devices in
DC Microgrids, such as converters and communication networks. To address various
situations and scenarios in DC Microgrids, it will take more work to overcome the
drawbacks of current protection schemes due to the absence of standardised
procedures and restricted participation. Future studies should concentrate on
developing and improving protection plans while assuring their adaptability and
efficacy for a range of operational circumstances. Due to their self-sustaining
character and incorporation of distributed energy resources (DERs) that may function
independently during grid outages, DC Microgrids are becoming more and more
popular. DC Microgrids have a number of benefits, including increased energy
efficiency, cost-effectiveness, dependability, safety, and simplicity. However, DC
Microgrids face considerable issues with regard to protection.

20
 Sharma et al (2022) introduces a cutting-edge protection strategy based on
transient power characteristics for DC microgrids. To ensure accurate failure
detection, the method includes main and localised backup protection. Without relying
on synchronous data or high-speed communication, the primary protection checks the
polarity of transient power at both ends of the cable to identify internal problems.
However, the primary defence might not be enough in the event of a communication
breakdown. In order to detect failures as a backup, the localised backup method
measures the variation in average transient power at one end of the cable.
Performance of the suggested protection plan is assessed at various points throughout
the system for various low resistance and high resistance pole-to-pole and pole-to-
ground fault types. According to simulation data, the localised backup protection
scheme identifies faults in less than 1 ms overall, while the primary protection
scheme does so in less than 70 and 200 milliseconds, respectively. This total
detection time takes into account communication latency. Further system transients,
such as AC side faults, loud surroundings, load changes, DG outages, and generation
uncertainty are used to confirm the proposed scheme's robustness. The suggested
scheme's advantages in terms of speed, accuracy, and sensitivity for fault detection
and transients in the system are highlighted by comparison with existing techniques in
the literature.

Rao and Jena (2022) proposed the resistance is estimated using the local
measurements that are available on the bus. Faults can be quickly found by
comparing the sign of the predicted resistance at the line segment's two ends. By
doing away with time synchronisation, this method makes detection easier. The
proposed method is applicable to DC microgrids with radial and ring configurations.
Using EMTDC software simulations on a ring main DC microgrid system, we verify
the methodology. Additionally, using technology that simulates different conditions,
we experimentally test the suggested approach. The simulation and experimental
findings show how well the suggested method works for precisely identifying faults,
such as close-in faults and high-resistance faults, within the DC microgrid. This line
parameter-based strategy exhibits encouraging potential as a trustworthy.

Prince et al (2021) propose a fault detection system for the DC microgrid
system using IEEE 9-bus. Our defence system includes 18 protective devices (PDs),

21
which can quickly identify and isolate problematic bus segments without shutting
down the entire system. The total fault current contributes significantly to quickly
locating the defective wires. Our technique achieves a remarkable accuracy of 95% in
estimating the threshold value by examining the maximum threshold peak of the
difference between forward and backward fault current. Our suggested solution
achieves effective defective line detection and isolation under pole-pole fault
circumstances while being less sophisticated than existing algorithms. Due to the
availability of low-passivity-based distributed energy, DC microgrids demonstrate
rapid changes in fault current compared to typical AC power systems. This feature
creates extra difficulties in fault detection and identification, along with the small
magnitude of the fault current. In the 9-bus DC microgrid system, our cutting-edge
protection system effectively locates short-circuits and isolates faults. This is done by
using a solid-state circuit breaker to isolate faults using a cumulative sum-based
method. Analysing locally obtained current and voltage signals at the borders reveals
the defective line. After that, the defective branch is isolated by tripping at each
system node.

Zubieta et al (2021) proposed the protection idea is that it can identify defects
that conventional approaches could miss, such as high resistance faults as well as low
impedance faults. Furthermore, the idea enables the addition of impedance to the
distribution line, which effectively causes the current di/dt to slow down in the event
of a short circuit problem. This lessens the strain on the components in charge of
cutting off the fault current. The protection strategy is especially well suited for
power distribution systems based on DC microgrids, where all loads or prosumers
supplied by the distribution network have energy storage resources. The protection
strategy can successfully separate load and local generation transients from the power
exchanged with the DC distribution line by making use of the energy storage
resources present at prosumers. Experimental implementation and deployment have
been conducted at a DC microgrid demonstration in Albuquerque, New Mexico, as
part of the Emera Technologies Block Energy System development, to confirm the
concept's efficacy. This demonstration's actual use of the protection concept is
evidence of its viability and potential for use in future DC microgrid-based power
distribution systems.

22
 Zhang et al (2021) presented Ring microgrids are given a revolutionary
differential protection system that emphasises the bus's power change rate as a crucial
factor. In order to ensure optimum detection sensitivity during short-circuit
occurrences and rapid fault indication, the technique makes use of the differential
power change rate between the two sides of the bus. This strategy dramatically
shortens the time it takes for the fault current to reach the action threshold in contrast
to traditional protection methods based on current, speeding up the total fault
detection procedure. The proportionality to the square of the current and
consideration of higher orders strengthen the scheme's effectiveness by enhancing
change rate responsiveness and sensitivity to even little flaws. Additionally, its
proportionality to the short-circuit impedance greatly widens the range of fault
detection, improving protection sensitivity throughout the entire microgrid. Numerous
simulations have been run to verify the effectiveness of the suggested protection
system. The findings show considerable advances in responsiveness, speed, and
interference resistance. Notably, the plan retains good selectivity for differential
protection, guaranteeing that, in the event of a malfunction, the system as a whole is
protected while just the afflicted portion of the microgrid is isolated.

Bayati et al (2019) takes advantage of current transients seen during faults to
create a localised framework for locating faults and figuring out resistance. A
distinguishing feature is the lack of communication linkages because the fault
location and resistance calculation are carried out independently. The suggested
method makes computation of fault resistance and location easier by developing a
mathematical equation defining current and voltage behaviour. Importantly, this
approach does not require any communication linkages to be established during fault
resistance or location assessment. Experimental results show that the technique is
effective, with fault location and resistance calculation precision for component and
line faults of less than 5%. It's significant that the suggested approach is easily
adaptable to ring-configured DC microgrids, supporting faults with different
resistance levels. Additionally, the plan can adjust to dynamic changes in operational
modes and topology, providing complete protection for DC microgrids. Results from
simulations confirm the proposed algorithm's efficacy and demonstrate its superiority
when compared to existing alternatives. The proposed protection strategy's ability to
accommodate the bidirectional current flow that is innate to ring systems makes it

23
stand out from other approaches. Only locally acquired measurements are used in the
developed mathematical equations for fault location and resistance computation. On
the Digsilent platform, a multi-source ring-type DC microgrid is used to rigorously
evaluate the fault location technique. The results support the suggested method's
robustness in the face of various fault locations and resistances.

24
 CHAPTER 3

PROBLEM FORMULATION AND OBJECTIVES

3.1 Problem Formulation

DC microgrids are a novel approach to effective and dependable electricity
distribution as a result of the rapid development in energy consumption and the
emergent obligation for justifiable power generation. An area-specific power system
called a DC microgrid allows for the assimilation of renewable power sources,
increased energy efficiency, and increased grid dependability. It can run
independently or in cooperation using the primary grid. The development of DC
microgrids as a possible substitute for conventional AC grids is a result of the
increasing requirements for clean and sustainable energy resolutions as well as the
requirement for efficient and reliable power delivery. A DC microgrid is a minor
measure power system that runs independently of or concurrently with the higher
grid, enabling the use of green energy options, enhancing energy efficiency, and
improving overall grid stability. Designing an effective DC microgrid involves
addressing various challenges related to system requirements, component selection,
control strategies, simulation modeling, optimization, and implementation. The first
step in designing a DC microgrid is to define the system requirements accurately.
This involves determining the power demand, load characteristics, voltage levels, and
operational modes. The power demand serves as a fundamental parameter that
influences the selection of components and the design of control schemes to
encounter the vitality needs of the microgrid. The scheme requirements also
encompass factors such as grid connection options, islanded operation capabilities,
and the desired level of reliability and stability. Once the system requirements are
established, the next step is to select appropriate components for the DC microgrid.
This includes PV panels, wind turbines, battery energy storage systems (BESS),
power converters, and other auxiliary equipment. Component selection is based on
factors such as power generation capacity, efficiency, cost, reliability, and
compatibility with the overall system design. The chosen components should align
with the available renewable energy sources and meet the load requirements of the
microgrid. To accurately simulate the behavior of the components within the DC

25
microgrid, mathematical models need to be developed. These models capture the
power generation characteristics of the PV panels and wind turbines, the dynamics of
the BESS, and other relevant components. The mathematical models serve as the
foundation for simulating and analyzing the performance of the microgrid under
various load scenarios and operating characteristics. The models should accurately
represent the nonlinear characteristics, time-varying dynamics, and interactions
between the components. Designing effective control strategies is crucial for
managing power flow, voltage regulation, and energy management within the DC
microgrid. Control algorithms need to be developed for numerous aspects, including
maximum power point tracking (MPPT) to optimize renewable energy generation,
energy storage management, load balancing, and unified switching among electrically
linked and island operating modes. These control strategies ensure efficient utilization
of available resources, stable grid operation, and effective management of energy
storage systems. Once the microgrid design is validated, it can be implemented in a
hardware setup for further testing. Comprehensive testing is accompanied to
authenticate the enactment, stability, and reliability of the microgrid under real-world
conditions. This testing phase ensures that the design functions as intended and meets
the desired objectives, such as power demand fulfillment, voltage stability, and
energy efficiency. Field tests can involve connecting actual sources of green energy,
energy storage devices, and demands to evaluate the system's behavior and validate
its performance. The design of a DC microgrid using MATLAB requires a systematic
and comprehensive approach that considers system requirements, component
selection, mathematical modeling, control strategy design, simulation model
development, fine-tuning, validation, implementation, and continuous monitoring. By
following this methodology, engineers and researchers can design and analyze DC
microgrids that integrate renewable energy sources, meet power demand
requirements, enhance energy efficiency, and improve overall grid stability. The
utilization of MATLAB provides powerful tools for modeling, simulation, control
algorithm development, and optimization, enabling the efficient design and
optimization of DC microgrids. The successful implementation of a well-designed
DC microgrid can contribute significantly to the transition concerning a more viable
and resilient energy future.

26
3.2 Problem Statement

The problem statement of this research work revolves around the design and analysis
of a DC microgrid using MATLAB. A DC microgrid is a confined power distribution
system that integrates various components, such as photovoltaic (PV) panels, wind
turbines, energy storage systems (ESS), and power converters, to efficiently generate,
store, and distribute electricity. The aim of this research is to address the challenges
associated with the design and optimization of a DC microgrid, focusing on
maximizing the utilization of renewable energy sources, managing power flow and
voltage regulation, and ensuring reliable and efficient energy management within
the microgrid. One of the primary challenges in designing a DC microgrid is to
effectively utilize renewable energy sources, such as PV panels and wind turbines.
These sources are inherently intermittent and highly dependent on environmental
conditions, which makes it crucial to implement. The research aims to investigate and
develop efficient MPPT algorithms that can optimize the power generation from
renewable sources, thereby maximizing the utilization of clean energy and reducing
reliance on conventional energy sources.

3.3 Objectives

 To design the hybrid renewable system (wind energy, photovoltaic power, and
a battery) in MATLAB/Simulink.

 Implementation of Hybrid renewable sources in DC Microgrid for maximum
Output Power.

 Analysis of Faults

a) Analysis of Faults with grid and PV system

b) Analysis of Faults with grid and wind form.

c) Analysis of Faults PV, wind and AC source.

27
 CHAPTER 4

METHODOLOGY

4.1 Introduction

Since their capability to completely alter the way power is distributed, DC microgrids
have attracted a lot of attention lately. A DC localised electrical network called a
"microgrid" incorporates various distributed energy resources (DERs), energy storage
systems, and loads in a DC distribution network. Unlike traditional AC grids, DC
microgrids offer numerous advantages, including higher efficiency, improved power
quality, expanded use of green power resources. The increasing demand for clean and
sustainable energy sources has led to a pattern modification in the way power systems
are designed and operated. One promising solution to address this challenge is the
perception of a DC microgrid. A DC microgrid is a localized power distribution
network that operates primarily on direct current (DC) and DERs such as solar
photovoltaic (PV) panels, wind turbines, ESS, and loads. Unlike traditional AC grids,
which are prevalent in most power systems, DC microgrids suggestion several
compensations in relations of efficiency, reliability, and flexibility. By utilizing DC
power, the need for multiple power conversions, as required in AC grids, is
significantly reduced, resulting in lower energy losses and improved overall system
efficiency.

4.2 Methodology

Designing a DC microgrid with PV panels, an AC grid connection, a wind farm, an
AC to DC converter, and analyzing fault occurrences on the DC line begins with
configuring the system. Figure 4.1 shows the complete dc-microgrid. Integrated PV
panels, wind turbines, and grid into the DC microgrid to harness renewable energy
sources. Design and model the PV and wind systems to capture maximum power
output based on solar irradiance and wind speed variations. Implement maximum
power point tracking (MPPT) algorithms for both the PV and wind systems to
continuously track and extract the maximum available power from these sources.
Consider different MPPT techniques and their compatibility with PV and wind
systems. Incorporate a battery storage system into the DC microgrid to store
excess energy from PV and wind sources.

28
Figure 4.1 DC-microgrid designed using MATLAB/Simulink

29
Design the battery system to handle charging and discharging cycles efficiently and
manage the energy flow within the microgrid. DC microgrid that integrates PV, wind,
battery storage, and grid connection. This system provides green energy generation,
energy storage capabilities, and the flexibility to function together in grid connected
and islanded modes, ensuring reliable and sustainable power supply. The power
ratings and specifications of each component are determined based on the desired
power demand and renewable energy generation capacity. Next, a mathematical
model is developed for the PV panels to simulate their power generation
characteristics, considering factors such as irradiance and temperature. An AC grid
connection is comprised in the microgrid to provide backup power and facilitate a
seamless switch among linked to the grid and isolated options. A control method is
designed to manage power transfer between microgrids and the AC grid, while
protection mechanisms are implemented to ensure safe operation during grid-
connected mode. Figure 4.2 shows the PV system designed for dc-microgrid.
Developed model of the PV array based on current-voltage (I/V) and power-voltage
(P/V) are two examples of its electrical properties. Current-voltage (I/V) and power-
voltage (P/V) are two examples of its electrical properties curves. This model should
consider factors like solar irradiance, temperature, and shading effects. Design and
simulate a DC-DC converter, such as a buck or boost converter, to regulate the
voltage from the PV array to match the DC microgrid voltage level. The converter
design should consider efficiency, stability, and control strategies. The incorporation
of energy storage, such as batteries or supercapacitors, in the PV system. Develop
control algorithms to manage the charge/discharge cycles of the energy storage
system built on the PV power generation and load demand.

30
 Figure 4.2 Designed PV system in MATLAB/Simulink

Figure 4.3 shows the designed wind generator for dc-microgrid. Model of the wind
turbine based on its aerodynamic characteristics, turbine power curve, and wind
speed. Consider factors such as wind speed variations, turbulence, and wind direction.
Implement a maximum power extraction algorithm to apprehension the extreme
available power from the wind turbine. a rectifier and DC-DC converter to convert
the variable AC output of the wind turbine into a regulated DC voltage suitable for
the microgrid. The designed wind generator system in MATLAB to analyze its
performance under varying wind speeds, turbulence, and load fluctuations. Evaluate
metrics such as power output, efficiency, and response time. design and optimize a
wind generator system for a DC microgrid, ensuring efficient power generation,
integration with energy storage, and reliable operation in different modes.

31
 Figure 4.3 Wind farm model designed in MATLAB/Simulink

Figure 4.4 shows the energy storage system in MATLAB. The appropriate battery
equipment (e.g., lithium ion, lead-acid, flow battery) based on the requirements of the
DC microgrid, such as energy capacity, power capability, efficiency, cycle life, and
cost. Consider factors like load demand, renewable energy generation, and expected
discharge duration. the optimal size (capacity) of the battery storage system to meet
the energy requirements of the DC microgrid. Consider factors like peak load
demand, renewable energy availability, desired backup duration, and system
reliability.

Figure 4.4 Designed storage system for dc-microgrid

32
 CHAPTER 5

RESULTS AND DISCUSSIONS

5.1 Introduction

DC microgrids have gained significant attention as a promising solution for efficient
and sustainable power distribution. They provide an alternative to traditional AC-
based grids, offering advantages such as higher efficiency, reduced transmission
losses, and the ability to integrate renewable energy sources effectively. In this
project, a DC microgrid is designed, incorporating photovoltaic (PV) power, wind
power, battery storage, and grid connection. The performance of the designed DC
microgrid was evaluated through simulations and analysis. The integration of PV
panels and wind turbines allowed for the effective utilization of renewable energy
sources. The PV system generated power during daylight hours, while the wind
system produced power during windy periods. This combination ensured continuous
power generation, reducing dependency on the grid. DC microgrids have emerged as
a promising solution for achieving efficient, reliable, and sustainable power
distribution in various applications. Unlike traditional AC grids, DC microgrids utilize
direct current (DC) for power transmission and distribution, offering several
advantages such as reduced conversion losses, improved system stability, and
seamless integration of renewable energy sources. In this research, a comprehensive
analysis of a DC microgrid is conducted to assess its performance, efficiency, and
feasibility in meeting the growing demand for clean and resilient energy solutions.

CASE 1:

5.2 Analysis of Fault with Grid and PV Based DC-Microgrid

A DC microgrid with an AC grid and PV system with DC converters combines both
DC and AC power sources within a microgrid infrastructure. The PV panels generate
DC electricity from sunlight. These panels convert solar energy into electrical energy
through the photovoltaic effect. In the event of a fault on the grid, where the power
supply from the grid becomes unavailable or unstable, a PV-based system can be
designed to switch to the PV source to provide power to the load. This can be
achieved through the use of appropriate control and switching mechanisms. Analysis

33
of the fault occurring at different intervals of time on ac-grid which causing the
switching on the PV source are carried out. Figure 5.1 shows the irradiance of the PV
plant started at t=0 sec which helps to assume that ac-grid is off at t =0 sec. The power
delivered to load is solely by the PV plant. Figure 5.2 shows the power delivered to
the load which is 10 kW.

Figure. 5.1 Irradiance of the PV plant started at t=0 sec

Figure. 5.2 Power delivered to load by PV plant

Figure 5.3 shows the ac-grid three phase output which is approximately 50 kV. At t=1
sec an fault occurs at ac-grid causing disruption at the output. Figure 5.4 shows the
irradiance of the PV plant started at t=1 sec to continue the flow of power to load.

34
 Figure 5.3 Output from ac-grid from t =0 to t=1 sec

Figure 5.4 Irradiance of the PV plant started at t=1 sec

The combined power delivered to load by ac-grid and PV plant is shown in Figure
5.5. A small glitch is seen at t=1 sec due to the fault occurring in the transmission and
switching of the supply to the PV plant. The power delivered to the load by ac-grid
and PV plant is approximately 10 kW. The recovery time for constant flow of power
is 0.1 sec.

35
Figure 5.5 Combined power delivered to load by ac-grid (from t=0 to t=1 sec) and PV
plant (from t =1 to t=5 sec)

Figure 5.6 illustrates the three-phase AC grid output, which has an approximate
voltage level of 50 kV. At t=2 sec, a fault occurs in the AC grid, causing a disruption
in the output. Conversely, Figure 5.7 displays the irradiance of the PV plant, which
starts at t=2 sec. The purpose of this figure is to demonstrate that despite the fault on
the AC grid, the PV plant continues to receive solar radiation. As a result, it can
generate power to supply the load..

Figure 5.6 Output from ac-grid from t =0 to t=2 sec

36
 Figure 5.7 Irradiance of the PV plant started at t=2 sec

Figure 5.8 depicts the combined power delivered to the load by the AC grid and PV
plant. At t=2 sec, a fault occurs in the transmission and switching process, resulting in
a minor disruption seen as a glitch in the power delivery. The total power supplied to
the load by the AC grid and PV plant throughout the entire simulation cycle is
approximately 10 kW. The system exhibits a fast recovery time of 0.1 sec to restore a
consistent and uninterrupted flow of power to the load.

Figure 5.8 Combined power delivered to load by ac-grid (from t=0 to t=2 sec) and PV
plant (from t =2 to t=5 sec)

Figure 5.9 shows the ac-grid three phase output which is approximately 50 kV which
is converted in to dc voltage. At t=3 sec a fault occurs at ac-grid causing disruption at
the output. Figure 5.10 shows the irradiance of the PV plant started at t=3 sec to
continue the flow of power to load.
37
 Figure 5.9 Output from ac-grid from t =0 to t=3 sec

Figure 5.10 Irradiance of the PV plant started at t=3 sec

The combined power delivered to load by ac-grid and PV plant is shown in Figure
5.11. A small glitch is seen at t=3 sec due to the fault occurring in the transmission
and switching of the supply to the PV plant. The power delivered to the load by ac-
grid (from t=0 to t=3sec) and PV (from t = 3 to t= 5sec) plant is for complete
simulation cycle is approximately 10 kW. The recovery time for constant flow of
power is 0.1 sec.

38
 Figure 5.11 Combined power delivered to load by ac-grid (from t=0 to t=3 sec) and
PV plant (from t =3 to t=5 sec)

Figure 5.12 shows the ac-grid three phase output which is approximately 50 kV which
is converted in to dc voltage. At t=4 sec a fault occurs at ac-grid causing disruption at
the output. Figure 5.13 shows the irradiance of the PV plant started at t=4 sec to
continue the flow of power to load.

Figure 5.12 Output from ac-grid from t =0 to t=4 sec.

39
 Figure 5.13 Irradiance of the PV plant started at t=4 sec

The combined power delivered to load by ac-grid and PV plant is shown in Figure
5.14. A small glitch is seen at t=4 sec due to the fault occurring in the transmission
and switching of the supply to the PV plant. The power delivered to the load by ac-
grid (from t=0 to t=4sec) and PV (from t = 4 to t= 5sec) plant is for complete
simulation cycle is approximately 10 kW. The recovery time for constant flow of
power is 0.1 sec.

Figure 5.14 Combined power delivered to load by ac-grid (from t=0 to t=4 sec) and
PV plant (from t =4 to t=5 sec)

40
The response of the DC microgrid with a PV source to a fault at the AC-grid section
can be observed from the provided table. The fault occurrence causes a noticeable
impact on various parameters within the microgrid. Firstly, the PV voltage
experiences a significant drop from 11.40 kV to 5.141 kV as the fault occurs,
indicating a disturbance in the PV system. However, the bus voltage remains
relatively stable throughout the fault, ranging from 245.10 V to 248.50 V. This
stability suggests that the microgrid is equipped with mechanisms to regulate the
voltage during such events, possibly including voltage control systems or energy
storage solutions. Moreover, the bus current shows minimal variation during the fault,
maintaining a relatively constant range between 40.84 A and 41.41 A. This indicates
that the fault does not result in significant disruptions to the current flow within the
microgrid. Similarly, the load power remains relatively stable, with a slight increase
from 10.03 kW to 10.34 kW.

Table 5.1 Response of dc-microgrid with PV source and fault at ac-grid section.

Fault Occurring PV Voltage Bus Voltage Bus Current Load Power
Time (sec) (kV) (V) (A) (kW)

0 11.40 245.10 40.84 10.03

1 10.27 246.10 41.02 10.15

2 8.893 246.90 41.15 10.21

3 6.270 247.70 41.28 10.27

4 5.141 248.50 41.41 10.34

CASE 2:

5.3 Analysis of Fault with Grid and Wind Farm Based DC-Microgrid

The integration of an AC grid and a wind farm in a DC-grid offers several advantages
and poses specific challenges. The AC grid serves as the main power source,
providing a reliable and stable electricity supply. Meanwhile, the wind farm
contributes renewable energy by harnessing wind power through wind turbines. AC
41
power generated by the wind farm undergoes conversion into DC power using power
electronic converters. Analysis of the fault occurring at different intervals of time on
ac-grid which causing the switching on the wind farm are carried out. Figure 5.15
shows the nominal wind speed subjected to wind farm for power generation assuming
that grid is at fault at t=0. The wind speed of 12 m/sec is applied to the farm and from
Figure 5.16 it can be inferred that the power generated by the farm gradually increases
and maintains it to 0.95 kW.

Figure 5.15 Wind speed profile from t=0 to t=5 sec

Figure 5.16 Power delivered to load by wind farm (from t =0 to t=5 sec)

Figure 5.17 shows the ac-grid three phase output which is approximately 50 kV which
is converted in to dc voltage. At t=1 sec a fault occurs at ac-grid causing disruption at
the output. Figure 5.18 shows the nominal wind speed profile started at t=1 to t=5 sec
to continue the flow of power to load.

42
 Figure 5.17 Output from ac-grid from t =0 to t=1 sec

Figure 5.18 Wind speed profile from t=1 to t=5 sec

The combined power delivered to load by ac-grid and wind is shown in Figure 5.19.
A glitch is seen at t=1 sec due to the fault occurring in the transmission and switching
of the supply to the wind farm output. The power delivered to the load by ac-grid
(from t = 0 to t = 1 sec) and wind farm (from t = 1 to t = 5sec) is for complete
simulation cycle is approximately 10 kW. The recovery time for constant flow of
power is 0.15 sec. The minima occurred at t = 1 sec is 0.45 kW.

43
 Figure 5.19 Combined power delivered to load by ac-grid (from t=0 to t=1 sec) and
wind farm (from t =1 to t=5 sec)

Figure 5.20 shows the ac-grid three phase output which is approximately 50 kV which
is converted in to dc voltage. At t=2 sec a fault occurs at ac-grid causing disruption at
the output. Figure 5.21 shows the nominal wind speed profile started at t=2 to t=5 sec
to continue the flow of power to load.

Figure 5.20 Output from ac-grid from t =0 to t=2 sec

44
 Figure 5.21 Wind speed profile from t=2 to t=5 sec

The combined power delivered to load by ac-grid and wind is shown in Figure 5.22.
A glitch is seen at t=1 sec due to the fault occurring in the transmission and switching
of the supply to the wind farm output. The power delivered to the load by ac-grid
(from t = 0 to t = 2 sec) and wind farm (from t = 2 to t = 5 sec) is for complete
simulation cycle is approximately 10 kW. The recovery time for constant flow of
power is 0.15 sec. The minima occurred at t = 2 sec is 0.45 kW.

Figure 5.22 Combined power delivered to load by ac-grid (from t = 0 to t = 2 sec) and
wind farm (from t = 2 to t = 5 sec)

45
Figure 5.23 shows the ac-grid three phase output which is approximately 50 kV which
is converted in to dc voltage. At t = 3 sec a fault occurs at ac-grid causing disruption
at the output. Figure 5.24 shows the nominal wind speed profile started at t = 3 to t =
5 sec to continue the flow of power to load.

Figure 5.23 Output from ac-grid from t = 0 to t = 3 sec

Figure 5.24 Wind speed profile from t = 3 to t = 5 sec

The combined power delivered to load by ac-grid and wind is shown in Figure 5.25.
A glitch is seen at t = 3 sec due to the fault occurring in the transmission and
switching of the supply to the wind farm output. The power delivered to the load by
ac-grid (from t = 0 to t = 3 sec) and wind farm (from t = 3 to t = 5 sec) is for complete
simulation cycle is approximately 10 kW. The recovery time for constant flow of
power is 0.15 sec. The minima occurred at t = 3 sec is 0.45 kW.

46
 Figure 5. 25 Combined power delivered to load by ac-grid (from t=0 to t=3 sec) and
wind farm (from t =3 to t=5 sec)

Figure 5.26 shows the ac-grid three phase output which is approximately 50 kV which
is converted in to dc voltage. At t = 4 sec a fault occurs at ac-grid causing disruption
at the output. Figure 5.27 shows the nominal wind speed profile started at t = 4 to t =
5 sec to continue the flow of power to load.

Figure 5.26 Output from ac-grid from t = 0 to t = 4 sec

47
 Figure 5.27 Wind speed profile from t = 4 to t = 5 sec

The combined power delivered to load by ac-grid and wind is shown in Figure 5.28.
A glitch is seen due to the fault occurring in the transmission and switching of the
supply to the wind farm output. The power delivered to the load by ac-grid (from t = 0
to t = 4 sec) and wind farm (from t = 4 to t = 5sec) is for complete simulation cycle is
approximately 10 kW. The recovery time for constant flow of power is 0.15 sec. The
minima occurred at t = 4 sec is 0.45 kW.

Figure 5.28 Combined power delivered to load by ac-grid (from t=0 to t=4 sec) and
wind farm (from t =4 to t=5 sec)

48
The response of the DC microgrid with a wind farm source to a fault at the AC-grid
section is depicted in Table 5.2. The fault occurrence affects various parameters
within the microgrid, allowing us to analyze its impact. Firstly, the bus voltage shows
an increasing trend throughout the fault, starting from 237.6 V and reaching 244.6 V
at the end. This suggests that the wind farm source continues to provide a stable
voltage supply despite the fault. The consistent increase in bus voltage indicates the
presence of voltage control mechanisms within the microgrid to maintain stable
operation. Similarly, the bus current experiences a gradual increase during the fault,
starting from 39.60 A and reaching 40.64 A. This indicates that the fault does not
disrupt the current flow significantly, and the microgrid manages to maintain a stable
current supply. It is worth noting that the load power also exhibits a gradual increase
from 9.433 kW to 10.16 kW, which correlates with the increasing bus voltage and
current. This suggests that the microgrid successfully delivers a consistent power
supply to the connected loads despite the fault.

Table 5.2 Response of dc-microgrid with wind farm source and fault at ac-grid
section.

Fault Occurring Bus Voltage Bus Current Load Power
Time (sec) (V) (A) (kW)

0 237.6 39.60 9.433

1 239.5 39.92 9.634

2 241.7 40.28 9.811

3 243.8 40.42 9.987

4 244.6 40.64 10.16

CASE 3:

5.4 Analysis of DC-Microgrid with PV, Wind and AC Source

The analysis of a DC microgrid involves examining various aspects of its design,
performance, and operation. One key area of analysis is the power generation, where
49
the performance of renewable energy sources like PV panels and wind turbines is
evaluated under different conditions. Figure 5.29 shows the three phase output power
from the grid. the grid provides the output of 50 kW of approximately 50 kW from
t = 0 to t = 1.5 sec. Figure 5.30 represents the irradiance input to a photovoltaic (PV)
plant in the DC microgrid. The excitation, or the period of significant irradiance,
begins at t = 1.5 seconds and continues until t = 3 seconds. During this specific time
zone of irradiance, the PV plant in the DC microgrid was able to generate power as
illustrated in Figure 5.31. Based on the details you provided, the power generated by
the PV plant during this irradiance period is approximately 12 kW.

Figure 5.29 Three phase output from the grid

Figure 5.30 Irradiance intensity input to PV panel

50
 Figure 5.31 Power output profile of PV plant

Figure 5.32 shows the excitation applied to the wind farm. The nominal wind speed of
12 m/sec applied to the farm which was started at t=3 sec to t =5 sec. During this time
period power is delivered to the load through batteries.

Figure 5.32 Nominal excitation applied to wind farm.

The state of charge (SOC) of batteries in a DC microgrid will be influenced by
various factors, including the power generation from renewable sources (such as the
PV plant and wind farm), the power consumption of loads, and the presence of energy
storage systems. If the power generated by the PV plant and wind farm during their
respective excitation periods exceeds the power consumption of the loads in the
microgrid, the excess power can be used to charge the batteries. This charging will
result in an increase in the SOC of the batteries.

51
Figure 5.33 shows the SOC profile of the storage system. During the complete cycle
of t =0 to t = 5sec. The SOC of batteries rises from 50% to 50.06%, since the charge is
being given load connected to the system, which is evident from the bus voltage
which 241.8V shown in Figure 5.34.

Figure 5.33 SOC of the batteries

Figure 5.34 Bus voltage profile during complete simulation time

52
Figure 5.35 shows the power delivered to the load during the complete simulation
time. During the first transition from t=0 to t=1.5 sec power is given by the power
grid. During t =1.5 to t=3 sec, power to the load is given by the PV plant and last
transition from t= 3 to t=5 sec, power to the load is given by the wind farm.

Figure 5.35 Power delivered to load connected to the system

5.5 S